A device and a method for breeding blueberry-specific mycorrhizal fungi. The device includes a container, where a bottom of the container is laid with perlite to form a perlite layer; an absorbent cotton is arranged on the perlite layer; a hole for planting is provided in the absorbent cotton and blueberry tissue culture seedlings or moss seedlings are placed in the hole; and a spore transfer solution is provided around the blueberry tissue culture seedlings or moss seedlings. When used as a bacterial fertilizer for inoculation in the field, the pieces of absorbent cotton are buried directly around the blueberry roots; while used for research, one of the pieces of the absorbent cotton is washed with sterile water and filtered with a filter paper to obtain mycorrhizal fungi spores.

A device and a method for breeding blueberry-specific mycorrhizal fungi. The device includes a container, where a bottom of the container is laid with perlite to form a perlite layer; an absorbent cotton is arranged on the perlite layer; a hole for planting is provided in the absorbent cotton and blueberry tissue culture seedlings or moss seedlings are placed in the hole; and a spore transfer solution is provided around the blueberry tissue culture seedlings or moss seedlings. When used as a bacterial fertilizer for inoculation in the field, the pieces of absorbent cotton are buried directly around the blueberry roots; while used for research, one of the pieces of the absorbent cotton is washed with sterile water and filtered with a filter paper to obtain mycorrhizal fungi spores.

The present invention relates to the production of propagation plugs, primarily small blocks of sphagnum for the growing of cuttings and seed plants, and of the type consisting of a cylindrical block having an envelope of paper or a similar material and an associated filling of sphagnum or a corresponding substrate material. The paper is an air permeable composite sheet material comprising a) a biodegradable nonwoven sheet material; and b) a hot melt adhesive comprising at least 50% w/w of one or more biodegradable bioplastics. The hot melt adhesive is supplied to at least a part of a face of the biodegradable nonwoven sheet material.

The present invention relates to the production of propagation plugs, primarily small blocks of sphagnum for the growing of cuttings and seed plants, and of the type consisting of a cylindrical block having an envelope of paper or a similar material and an associated filling of sphagnum or a corresponding substrate material. The paper is an air permeable composite sheet material comprising a) a biodegradable nonwoven sheet material; and b) a hot melt adhesive comprising at least 50% w/w of one or more biodegradable bioplastics. The hot melt adhesive is supplied to at least a part of a face of the biodegradable nonwoven sheet material.

Embodiments of the invention are biodegradable pods containing materials to repair damaged turf (lawns, fields). Each pod is sized and configured to repair an area ranging in size from about 9 square inches to about 36 square inches (60 cm.sup.2 to 230 cm.sup.2). The pods contain granulated ingredients including fertilizer, grass seed, gypsum, humic acid and calcium, in a material that expands when moistened. The pods are covered with a water-disruptable covering such as a polyvinyl alcohol film or a biodegradable paper.

The present invention relates to a distributor apparatus adapted for positioning individual pieces of a length of growth medium cut into pieces of suitable size into a propagation tray. The distributor apparatus comprises a plurality of distributor units configured to move between a loading position and an unloading position. Each distributor unit comprises an open-ended channel or cavity adapted for receiving a whole number of growth medium pieces. The distributor units, in a loading position, are positioned relatively to each other such that their open-ended channels or cavities are disposed in continuation to each other to form a receiving unit with an open-ended channel or cavity adapted for receiving a single length of growth medium pieces. The distributor units, when in an unloading position, are rotated, relative to their loading position, such that their open-ended channels or cavities are disposed parallel relative to each other.

The present invention relates to a distributor apparatus adapted for positioning individual pieces of a length of growth medium cut into pieces of suitable size into a propagation tray. The distributor apparatus comprises a plurality of distributor units configured to move between a loading position and an unloading position. Each distributor unit comprises an open-ended channel or cavity adapted for receiving a whole number of growth medium pieces. The distributor units, in a loading position, are positioned relatively to each other such that their open-ended channels or cavities are disposed in continuation to each other to form a receiving unit with an open-ended channel or cavity adapted for receiving a single length of growth medium pieces. The distributor units, when in an unloading position, are rotated, relative to their loading position, such that their open-ended channels or cavities are disposed parallel relative to each other.

An automated system for plant growth may include a reactor to make a hydrogel solution. A hopper with a processor controlled valve or valves may deliver components to make the hydrogel solution in the reactor. The hydrogel solution may be poured into a tray to create a hydrogel mat or a hydrogel plug. A conveyor may move the hydrogel mat or the hydrogel plug to a nursery on a path in which the hydrogel mat or the hydrogel plug is seeded and is dibbled or scratched. The nursery may include a first position for a seed to germinate in the hydrogel mat or the hydrogel plug, and a second position for a plant to grow to a harvest state in the hydrogel mat or the hydrogel plug. The nursery may include a plurality of LED lights suitable for growth of a plant from the germinated seed.

The present application is directed to a method of applying a plant growing material to a surface of a mold décor, the method comprising flocking at least one aquatic seed to the surface of a mold décor to adhere the at least one aquatic seed to the surface of the mold décor.

The present application is directed to a method of applying a plant growing material to a surface of a mold décor, the method comprising flocking at least one aquatic seed to the surface of a mold décor to adhere the at least one aquatic seed to the surface of the mold décor.